Virus-specific CD8+ T-cell responses play a pivotal role in limiting viral replication. Alterations in these responses, such as decreased cytolytic function, inappropriate maturation, and limited proliferative ability could reduce their ability to control viral replication. Here, we report on the capacity of HIV-specific CD8+ T cells to secrete cytokines and proliferate in response to HIV antigen stimulation. We find that a large proportion of HIV-specific CD8+ T cells that produce cytokines in response to cognate antigen are unable to divide and die during a 48-hour in vitro culture. This lack of proliferative ability of HIV-specific CD8+ T cells is defined by surface expression of CD57 but not by absence of CD28 or CCR7. This inability to proliferate in response to antigen cannot be overcome by exogenous interleukin-2 (IL-2) or IL-15. Furthermore, CD57 expression on CD8+ T cells, CD4+ T cells, and NK cells is a general marker of proliferative inability, a history of more cell divisions, and short telomeres. We suggest, therefore, that the increase in CD57+ HIV-specific CD8+ T cells results from chronic antigen stimulation that is a hallmark of HIV infection. Thus, our studies define a phenotype associated with replicative senescence in HIV-specific CD8+ T cells, which may have broad implications to other conditions associated with chronic antigenic stimulation.

CD8+ T cells are crucial to the recognition and clearance of virus-infected cells.1,2Fully functional CD8+ T cells have the ability to proliferate and mediate antiviral activity through cytokine and chemokine secretion, Fas/Fas ligand interactions, and/or perforin/granzyme-mediated cell lysis after recognition of cognate antigen. When naive CD8+ T cells are activated during a primary viral infection, they proliferate and become effector T cells that fulfill these functions.2 3 Following clearance of virus, the majority of the virus-specific CD8+ T cells die, and few memory CD8+ T cells remain to combat subsequent infections with further rounds of proliferation and elaboration of effector functions.

Studies have suggested that chronic stimulation of T cells, such as that which occurs with rheumatoid arthritis,4-6multiple myeloma,7 cytomegalovirus (CMV) and HIV infections,8,9 and following bone marrow transplantation10 can result in the development of CD8+ T cells that are capable of cytokine secretion yet incapable of cell division. Although the provenance and exact phenotype of such CD8+ T cells remain unclear,10-16 such a failure to proliferate is generally attributed to replicative senescence resulting from continual stimulation by antigen and/or cytokine. Indeed, it has been suggested that replicative senescence17-21 or “clonal exhaustion”22-24 of HIV-specific T cells may underlie the inability of T-cell immunity to suppress virus adequately. Other studies have suggested that deficiencies in HIV-specific CD8+ T-cell function may arise from insufficient CD4+ T-cell help25-28 or specific signaling and cytotoxic functional defects.25,29 30 

The phenotypes associated with replicatively senescent CD8+T cells are not well defined31,32 but are generally attributed to lack of CD28 or expression of CD577,30,33-36and are thought to result in the inability of these CD8+ T cells to proliferate.37,38 These T cells commonly are found in individuals with chronic immune activation,4,6-10,39,40 and they increase in frequency with age.41 42 We examined the relationship between CD57 expression and 2 functional aspects of HIV-specific, CMV-specific, and other CD8+ T cells: their ability to produce cytokines and to proliferate in response to stimulation by cognate antigen. We found that CD57+ HIV-specific CD8+ T cells, irrespective of CD28 or CCR7 expression, produce IFN-γ but are unable to proliferate in response to cognate peptide with costimulation. This proliferative defect was found in all CD57-expressing CD4+and CD8+ T cells and NK cells and could not be overcome by the addition of exogenous interleukin-2 (IL-2) or IL-15. We also show that CD57+ lymphocytes have undergone more cell divisions compared with other memory cells of other phenotypes. Finally, expression of CD57 renders cells susceptible to activation-induced cell death by apoptosis. Notably, the phenotype we describe here is not predicted by lack of CD28 or CCR7 expression but is defined by expression of CD57.

Study subjects

For this study, 30 HIV-1–infected subjects were recruited at the University of Texas Southwestern Medical Center and the National Institutes of Health. As detailed in Table1, the study subjects include those who have been treated with antiretroviral drugs and those who are treatment naive. Viral loads were determined using either the Roche Amplicor Monitor assay or the Roche Ultradirect assay (Basel, Switzerland). All subjects gave informed consent prior to entry into this study, and all studies were approved by the institution's institutional review board.

Table 1.

Study subjects

SubjectCD4 count,
cells/μL
Viral load,
copies/mL
Duration of treatment, yDuration of infection, y
693 3 996 — 15 
636 1 800 — > 12 
327 125 — > 12 
875 10 152 — > 3 
1311 12 226 — > 15 
648 4 846 — 8  
750 4 800 — > 6 
255 22 950 — > 3 
577 24 135 — > 2 
10 335 110 950 — < 10 
11 742 170 044 — < 1 
12 369 6 401 — < 2 
13 706 13 930 — < 1 
14 1130 49 980 — < 1 
15 64 65 000 — > 1 
16 181 71 712 — > 6 
17 227 446 000 — < 4 
18 824 16 584 — < 2 
19 718 44 389 — < 4 
20 705 832 11  > 11 
21 190 1 005 > 6 
22 636 2 546 > 5 
23 588 5 936 > 8 
24 307 13 838 > 4 
25 869 18 049 > 5 
26 723 18 393 > 3 
27 462 18 480 10  > 10 
28 131 47 760 > 5 
29 412 84 093 > 4 
30 403 120 > 2 
31 HIV− HIV− HIV− HIV− 
SubjectCD4 count,
cells/μL
Viral load,
copies/mL
Duration of treatment, yDuration of infection, y
693 3 996 — 15 
636 1 800 — > 12 
327 125 — > 12 
875 10 152 — > 3 
1311 12 226 — > 15 
648 4 846 — 8  
750 4 800 — > 6 
255 22 950 — > 3 
577 24 135 — > 2 
10 335 110 950 — < 10 
11 742 170 044 — < 1 
12 369 6 401 — < 2 
13 706 13 930 — < 1 
14 1130 49 980 — < 1 
15 64 65 000 — > 1 
16 181 71 712 — > 6 
17 227 446 000 — < 4 
18 824 16 584 — < 2 
19 718 44 389 — < 4 
20 705 832 11  > 11 
21 190 1 005 > 6 
22 636 2 546 > 5 
23 588 5 936 > 8 
24 307 13 838 > 4 
25 869 18 049 > 5 
26 723 18 393 > 3 
27 462 18 480 10  > 10 
28 131 47 760 > 5 
29 412 84 093 > 4 
30 403 120 > 2 
31 HIV− HIV− HIV− HIV− 

Clinical information for subject cohort. — indicates treatment naive.

Peptides

15-mer peptides overlapping by 11 amino acids and corresponding to sequences of clade B HXBc2/Bal R5 chimeric HIV strain (gag, pol, env, nef) were pooled into mixture groups by HIV proteins as previously described.43 

Identification of HIV-specific CD8+ T cells (6-hour assay)

Peripheral blood mononuclear cells (PBMCs) were isolated and, in some instances, viably cryopreserved until later use. Stimulation was performed on fresh or frozen PBMCs as previously described.43,44 In every experiment a negative control (anti-CD28/CD49d) was included to control for spontaneous production of IFN-γ, as well as a positive control (Staphylococcusenterotoxin B (SEB) 1 μg/mL final, Sigma, St Louis, MO) to ensure that cells were responsive. Cultures were incubated for 1 hour at 37°C, followed by an additional 5 hours in the presence of Brefeldin-A (BFA) (1 μg/mL, Sigma). CD8+ T cells that produce effector cytokines following antigenic-specific stimulation are contained within and are thought to represent the tetramer-binding CD8+ T cells.43 45-47 

Antigen-specific proliferation (48-hour assay)

PBMCs were initially stained with carboxyfluorescein diacetate succinimidyl ester (CFSE; Molecular Probes, Eugene, OR) as previously described.48 These PBMCs were suspended in media supplemented with IL-2 (10 U/mL, Sigma) or IL-15 (100 ng/mL, R&D Systems, Minneapolis, MN) and were then stimulated with HIV peptide pools as described.43 44 Cells were then incubated for 36 hours at 37°C followed by an additional 12 hours in the presence of Brefeldin-A (10 μg/mL, Sigma). Cells were then stained for flow cytometric analysis. The percentage of HIV-specific CD8+ T cells was determined as in the previous paragraph. The proportion of CD8+ T cells that showed CFSE dilution (division) at 48 hours was divided by 2 (a cell division represents a 2-fold increase in frequency, hence the percentage of proliferated CD8+ T cells must be halved) and then divided by the 6 hours' response; for instance ([1/2 48 hour divided response]/6 hours response). This number represents the percentage of antigen-specific CD8+ T cells that had divided in response to antigenic stimulation.

Mitogen and superantigen stimulations

For superantigen stimulations SEB (Sigma) was used at 1 μg/mL. For mitogenic stimulations phytohemagglutinin (PHA) (Sigma) was used at 5 μg/mL. PBMCs stimulated with SEB were cultured for 4 days prior to immunofluorescent staining, and PHA-stimulated PBMCs were cultured for 2 days prior to propidium iodide staining. For apoptosis studies, SEB-stimulated PBMCs were cultured for 24 hours in the presence of activated caspase 3 binding peptide Z-VK(biotin)D(OMe)-FMK at 43 μg/mL (Enzyme Systems Products, Livermore, CA).

Immunofluorescence staining

Stimulated PBMCs were washed and then surface stained with directly conjugated antibodies to CD3 and other surface markers (Becton Dickinson Immunocytometry Systems (BDIS), San Jose, CA) for 20 minutes on ice. The cells were washed and fix/permeabilized (fixation/permeabilization solution [BDIS]), and stained with directly conjugated antibodies to IFN-γ or other intracellular molecules (as required for specific experiments), and resuspended in 1% paraformaldehyde in phosphate-buffered saline.

Flow cytometric analysis

Using a FACScalibur flow cytometer (BDIS), 6-parameter flow cytometric analysis was performed. Fluorescein isothiocyanate (FITC) or CFSE, PE, PerCP, and allophycocyanin (APCs) were used as the fluorophores. At least 100 000 live CD3+lymphocytes were collected. Twelve-parameter flow cytometric analysis was performed using a modified FACSDIVA flow cytometer (BDIS). Alexa 430, FITC, PE, Texas-Red PE, Cy5PE, Cy5.5PE, Cy7PE, APC, Cy7APC, and Alexa 594 were used as fluorophores. The list-mode data files were analyzed using PAINT-A-GATE software (BDIS) and FlowJo software (Tree Star, San Carlos, CA). CFSE distributions were analyzed using FlowJo software.

Cell sorting

Cell sorting was accomplished using a FACSDiva cell sorter (BDIS). FITC, PE, Cy5PE, and APC were used as the fluorophores. At least 10 000 cells were sorted for PCR analysis, and at least 106 cells were sorted for telomere length and cell-division analysis.

NK cells were magnetically sorted by a positive selection method with use of anti-CD16 antibodies conjugated to microbeads (Miltenyi Biotec, Auburn, CA).

T-cell receptor excision circle analysis

Quantification of T-cell receptor excision circle (TREC) in sorted CD8+ T cells was performed by real-time quantitative PCR by means of the 5′ nuclease (TaqMan) assay with an ABI7700 system (PerkinElmer, Norwalk, CT) as previously described.49 50 

Telomere length analysis

Telomere length analysis was performed using peptide nucleic acids (Dako, Carpinteria, CA) as previously described.51 52 Analysis was accomplished by comparing mean fluorescence intensity of the telomere channel between different populations that were all gated for similar DNA content (propidium iodide fluorescence) between samples.

Statistical analysis

Correlations were performed by Spearman rank correlation, and statistical significances were performed by Wilcoxon matched pairs test using Prism 3.0 software (San Diego, CA).

Proliferative defect in HIV-specific CD8+ T cells

As functional defects of antigen-specific T cells in humans recently have been described in HIV infection, we analyzed antigen-specific CD8+ T-cell responses in healthy and HIV-infected subjects by IFN-γ secretion and proliferation by flow cytometry. Figure 1A illustrates this using PBMCs from a healthy HLA-A2+ individual (subject 31), which we labeled with CFSE and stimulated with the HLA-A2–restricted CMV pp65 peptide (NLVPMVATV). After 6 hours, 27% of CD8+ T cells produced IFN-γ but had not divided. By 48 hours, 13% of the CD8+ T cells had divided and continued to produce IFN-γ. The percentage of responding CD8+ T cells and their ability to proliferate were assessed also by tetramer analysis to assure that the IFN-γ–producing CD8+ T cells adequately represented the antigen-specific CD8+ T cells (data not shown). Despite this relatively high percentage of antigen-specific CD8+ T cells, this response clearly demonstrated that the described assay could be used to monitor proliferation in response to antigenic stimulation.

Fig. 1.

Antigen-specific proliferation of CMV and HIV-specific CD8+T cells.

PBMCs, obtained from subjects 31, 15, 12, and 17 (A-D, respectively), were CFSE labeled and incubated with either the HLA-A2–restricted CMV pp65 peptide (A) or overlapping peptides encompassing the HIV gag protein (B-D). The cells were cultured for either 6 or 48 hours and then labeled with anti–CD3 PerCP, anti–CD8 APC, and anti–IFN-γ-PE. The flow cytometric data represent gated CD3+CD8+ T cells and is demonstrated as follows: background (costimulatory antibodies alone, left), 6-hour stimulation (center, left), and 48-hour stimulation dot plots (center, right) and CFSE histogram (right). The Y-axes in the dot plots represent staining for IFN-γ. Red dots represent CD8+ T cells that produced IFN-γ but did not divide. Blue dots correspond to IFN-γ+ proliferating CD8+ T cells, and green dots correspond to IFN-γ–proliferating CD8+ T cells. The numbers represent the total antigen-specific response at 6 hours. Gray dots represent CD8+ T cells that did not proliferate or produce IFN-γ.

Fig. 1.

Antigen-specific proliferation of CMV and HIV-specific CD8+T cells.

PBMCs, obtained from subjects 31, 15, 12, and 17 (A-D, respectively), were CFSE labeled and incubated with either the HLA-A2–restricted CMV pp65 peptide (A) or overlapping peptides encompassing the HIV gag protein (B-D). The cells were cultured for either 6 or 48 hours and then labeled with anti–CD3 PerCP, anti–CD8 APC, and anti–IFN-γ-PE. The flow cytometric data represent gated CD3+CD8+ T cells and is demonstrated as follows: background (costimulatory antibodies alone, left), 6-hour stimulation (center, left), and 48-hour stimulation dot plots (center, right) and CFSE histogram (right). The Y-axes in the dot plots represent staining for IFN-γ. Red dots represent CD8+ T cells that produced IFN-γ but did not divide. Blue dots correspond to IFN-γ+ proliferating CD8+ T cells, and green dots correspond to IFN-γ–proliferating CD8+ T cells. The numbers represent the total antigen-specific response at 6 hours. Gray dots represent CD8+ T cells that did not proliferate or produce IFN-γ.

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To examine cytokine secretion and proliferation in HIV-specific CD8+ T cells, we stimulated PBMCs from 11 HIV-infected subjects with a pool of overlapping 15-mer peptides encompassing HIV gag.43 45 In contrast to the CD8+ T-cell proliferation observed for CMV-specific CD8+ T cells from subject 31, a high proportion of HIV-specific CD8+ T cells did not proliferate (Table 2). Three patterns of responsiveness were apparent, as summarized in Figure 1B-D. HIV gag-specific CD8+ T cells from subject 15 were capable of proliferation and continued to produce IFN-γ after 48 hours, similar to the CMV-specific CD8+ T cells from subject 31 (Figure 1B). In contrast, HIV gag-specific CD8+ T cells from subject 12 continued, at least in part, to produce IFN-γ for 48 hours, yet failed to proliferate (Figure 1C). Finally, subject 17 showed strong (6%) but short-lived IFN-γ production in HIV gag-specific CD8+ T cells, and no subsequent proliferation (Figure 1D). These patterns of responsiveness were not restricted to CD8+ T cells specific for gag, as many subjects had detectable CD8+ T-cell populations specific for other HIV proteins that contained similarly deficient proliferative potential (data not shown).

Table 2.

Cell division of antigen-specific (HIV and CMV) CD8+ T cells

Subject6 hours48 hoursNo divisionDivision% CD57+% CCR7+% CD28+% CD27+
24 3.5 2.5 1.9 0.7 61 15 65 72 
6.5 3.9 2.3 1.6 44 56 81 
3.8 2.8 1.8 1.0 43 15 51 72 
2.6 0.5 0.3 0.3 70 8.5 45 43 
12 3.4 1.5 1.2 0.3 60 48 43 
17 6.3 0.2 0.1 0.1 76 45 76 
14 4.8 5.0 2.9 2.1 33 14 54 91 
15 4.7 9.8 3.6 6.2 18 12 68 87 
16 7.5 1.4 0.9 0.4 56 9.5 42 44 
27 2.6 1.2 0.7 0.5 55 35 77 
13 2.1 0.6 0.6 77 45 61 
31 27.4 25 11.4 13.4 21 19 76 93 
R2 — — — — 0.90 0.28 0.48 0.33 
Subject6 hours48 hoursNo divisionDivision% CD57+% CCR7+% CD28+% CD27+
24 3.5 2.5 1.9 0.7 61 15 65 72 
6.5 3.9 2.3 1.6 44 56 81 
3.8 2.8 1.8 1.0 43 15 51 72 
2.6 0.5 0.3 0.3 70 8.5 45 43 
12 3.4 1.5 1.2 0.3 60 48 43 
17 6.3 0.2 0.1 0.1 76 45 76 
14 4.8 5.0 2.9 2.1 33 14 54 91 
15 4.7 9.8 3.6 6.2 18 12 68 87 
16 7.5 1.4 0.9 0.4 56 9.5 42 44 
27 2.6 1.2 0.7 0.5 55 35 77 
13 2.1 0.6 0.6 77 45 61 
31 27.4 25 11.4 13.4 21 19 76 93 
R2 — — — — 0.90 0.28 0.48 0.33 

Values are listed as a percentage of total CD8+ T cells that produced IFN-γ after 6 hours and 48 hours, and IFN-γ–producing cells that had or had not divided after 48 hours (columns 2-5). Percentages of antigen-specific CD8+ T cells that express listed surface molecules are also shown (columns 6-9). R2 describes correlation based on linear regression between expression of individual surface molecules with the percentage of those CD8+ T cells that proliferated in response to antigenic stimulation (last row).

HIV-specific CD8+ T cells that do not proliferate are defined by CD57 expression

Having determined the proliferative potential of the HIV-specific CD8+ T cells (Figure 1; Table 2), we sought to define phenotypic markers that might differentiate proliferating from nonproliferating HIV-specific CD8+ T cells (Table2).

As shown in Table 2, CD57 was the only surface marker we found that alone defined the proliferative ability of HIV-specific CD8+ T cells (Figure 2; Table2). In addition to surface molecules listed in Table 2, we also studied expression patterns of CD152, CD11b, CD45RA, CD95, and CD45RO by HIV-specific CD8+ T cells but found that these molecules did not differ between T cells that proliferated and those that did not. A recent study suggested that CCR7 T cells were unable to proliferate.30 We sorted, by flow cytometry, CCR7 cells from subject 15. When we stimulated these CCR7 PBMCs (which contained the HIV-specific CD8+ subset) with peptides encompassing HIV gag, the T cells recognizing the HIV peptides were clearly capable of cell division (Figure 2). Thus, HIV-specific CD8+ T cells from one individual (subject 15) lacked CCR7 expression but maintained the ability to proliferate in response to antigenic stimulation, indicating that CCR7 expression was not a reliable predictor of proliferative potential of HIV-specific CD8+ T cells.

Fig. 2.

Antigen-specific proliferation of CCR7 HIV-specific CD8+ T cells.

PBMCs were obtained from subject 15 and labeled with anti–CCR7 PE antibody (A). CCR7 cells were sorted by flow cytometry (B), followed by CFSE labeling and 48 hours of HIVpeptide stimulation (C). Red and gray dots represent CCR7and CCR7+ cells, respectively (A-B). Red, blue, and gray dots are as in Figure 1 (C-G). In a separate experiment, PBMCs were obtained from subject 15 (proliferating) and subject 17 (nonproliferating) followed by 6 hours of stimulation with HIV-peptides as described in “Patients, materials, and methods.” Cells were then labeled with anti–CD3 PerCp, anti–CD8 APC, anti-CCR7 (D-E), or anti–CD57 PE (F-G) and anti–IFN-γ FITC. The data are gated for CD3+CD8+ T cells. In panels D-G, blue dots represent CD8+ T cells that express the marker of interest but did not produce IFN-γ. Red dots correspond to CD8+ T cells that produced IFN-γ but did not express the marker of interest. Finally, green dots represent CD8+ T cells that expressed the marker of interest and produced IFN-γ. This experiment was repeated with PBMCs from the same subject to assure reproducibility.

Fig. 2.

Antigen-specific proliferation of CCR7 HIV-specific CD8+ T cells.

PBMCs were obtained from subject 15 and labeled with anti–CCR7 PE antibody (A). CCR7 cells were sorted by flow cytometry (B), followed by CFSE labeling and 48 hours of HIVpeptide stimulation (C). Red and gray dots represent CCR7and CCR7+ cells, respectively (A-B). Red, blue, and gray dots are as in Figure 1 (C-G). In a separate experiment, PBMCs were obtained from subject 15 (proliferating) and subject 17 (nonproliferating) followed by 6 hours of stimulation with HIV-peptides as described in “Patients, materials, and methods.” Cells were then labeled with anti–CD3 PerCp, anti–CD8 APC, anti-CCR7 (D-E), or anti–CD57 PE (F-G) and anti–IFN-γ FITC. The data are gated for CD3+CD8+ T cells. In panels D-G, blue dots represent CD8+ T cells that express the marker of interest but did not produce IFN-γ. Red dots correspond to CD8+ T cells that produced IFN-γ but did not express the marker of interest. Finally, green dots represent CD8+ T cells that expressed the marker of interest and produced IFN-γ. This experiment was repeated with PBMCs from the same subject to assure reproducibility.

Close modal

We further confirmed the association between CD57 expression and proliferative inability in 2 ways. First, in subject 15, whose CD8+ T cells proliferated in response to HIV gag, all the IFN-γ–producing cells were CD57 and CCR7. However, in subject 17, whose CD8+ T cells did not proliferate in response to HIV gag, all the IFN-γ–producing cells were CD57+. Second, the percentage of CD57+ HIV gag-specific CD8+ T cells was inversely proportional to the percentage of gag-specific CD8+ T cells that had divided after 48 hours (R2 = 0.90, P < .0001) (Table 2). These data confirm that CD57 expression on HIV-specific CD8+ T cells defines an inability to divide in response to cognate antigen stimulation.

The presence of nondividing CD57+CD8+ T cells specific for HIV gag correlated with that of CD57+CD8+ T cells specific for HIV pol, env, and nef (R = 0.95, P < .0001), suggesting that the generation of such nondividing cells is related to the response to the whole pathogen rather than to individual antigens (Figure3A). In addition, the fraction of HIV-specific CD8+ T cells that are CD57+remained constant (the absolute number of CD57+HIV-specific CD8+ T cells decreased) following highly active antiretroviral therapy (data not shown). Figure 3B demonstrates that CD57 expression by CD8+ T cells specific for antigens other than HIV is only marginally correlated with expression of CD57 by HIV-specific CD8+ T cells (R = 0.58, P = .003). Whether this disparity is a result of differential cytokine expression by a significant proportion of HIV-specific CD8+ T cells or an underestimation of responses due to sequence differences or HIV accessory gene–specific CD8+ T cells remains unclear. However, it is clear that HIV-specific CD8+ T cells can contribute substantially (up to 80%) to the total CD57+CD8+ T-cell population in HIV-infected individuals.

Fig. 3.

Antigen-induced expression of CD57.

(A) Percentage of gag-specific CD8+ T cells that express CD57 was correlated with percentage nef, pol, or env-specific CD8+ T cells that express CD57, R = 0.95,P < .0001. (B). The percentage of gag-specific CD8+ T cells that express CD57 was correlated with the percentage of CD8+ T cells (specific for antigens other than HIV) that express CD57, R = 0.58, P = .003.

Fig. 3.

Antigen-induced expression of CD57.

(A) Percentage of gag-specific CD8+ T cells that express CD57 was correlated with percentage nef, pol, or env-specific CD8+ T cells that express CD57, R = 0.95,P < .0001. (B). The percentage of gag-specific CD8+ T cells that express CD57 was correlated with the percentage of CD8+ T cells (specific for antigens other than HIV) that express CD57, R = 0.58, P = .003.

Close modal

We also investigated the effect of CD57 expression on all T-cell subsets by stimulating CFSE-labeled PBMCs from 2 HIV-infected individuals and 5 HIV-uninfected subjects with superantigen. No proliferation was observed within the CD57+CD8+or CD57+CD4+ T cells. Furthermore, we studied proliferation of natural killer (NK) cells following stimulation with IL-2 and similarly found no proliferation within the NK cells, which expressed CD57 (data not shown). Hence, lack of proliferation by cells expressing CD57 is not restricted to HIV-specific CD57+CD8+ T cells but is a property of all T cells and NK cells.

It has been described that CD57 and CD28 expression by CD8+T cells are mutually exclusive.7,33,36 53 However, by multiparameter flow cytometric analysis of memory CD8+ T cells from 6 healthy subjects, we found that 4 populations of CD8+ T cells were evident by CD28 and CD57 expression (Figure 4). In all subjects there were considerable levels of CD8+ T cells that were either CD57+CD28+ or CD57CD28. Indeed, up to 20% (mean, 14%) of the memory CD8+ T cells from a cohort of 6 healthy individuals were either CD57+CD28+ or CD57CD28 (Figure 4, upper left). Furthermore, by stimulating CFSE-labeled PBMCs with the superantigen SEB, we found that virtually no cell division occurred in the CD57+ population regardless of CD28 expression (Figure 4, right histograms). Thus, CD28+ T cells that express CD57 are not capable of proliferation, whereas the CD28CD57 population contained proliferation-competent T cells (Figure 4, left histograms). These data were confirmed in a total of 6 individuals by stimulating PBMCs with anti-CD3, SEB, or phytohemagglutinin (PHA) and the CD57subset (regardless of CD28 expression) had statistically significantly more proliferation-competent CD8+ T cells than either CD57+ subset (Figure 4, bottom panel). These results demonstrate that lack of CD28 expression is neither the cause nor the predictor for lack of proliferative capacity.

Fig. 4.

Division of T-cell populations defined by their CD57 and CD28 expression patterns.

PBMCs from a healthy individual were stained with anti–CD57 FITC, anti–CD28 PE, anti–CD8 PerCp, and anti–CD45RA APC. Panel A shows the CD57 (x-axis) versus CD28 (y-axis) staining pattern of memory CD8+ T cells with CD45RA+CD28+events removed to examine the memory CD8+ T cells. The numbers represent the percentages of CD28+CD57, CD28+CD57+, CD28CD57+, and CD28CD57 populations. (B) PBMCs were CFSE labeled and stimulated with SEB for 4 days. Following stimulation, PBMCs were stained with CD57 PE, CD8 PerCP, and CD28 APC. CFSE histograms are demonstrated representing the CD28+CD57 population (upper left histogram), CD28+CD57+ population (upper right histogram), CD28CD57 population (lower left histogram), and CD28CD57+ population (lower right histogram). The numbers indicate the percentages of each population that had divided (calculated using the proliferation platform of FlowJo). These data are representative of experiments conducted on PBMCs from 6 separate individuals and using SEB, anti-CD3, or phytohemagglutinin as the stimulus (C). Wilcoxon matched pairs test demonstrated that the CD28CD57CD8+ T-cell populations contain significantly more proliferation-competent T cells compared with either CD57+CD8+ T-cell population (P = .004). Vertical bars represent the 25th to 75th percentiles.

Fig. 4.

Division of T-cell populations defined by their CD57 and CD28 expression patterns.

PBMCs from a healthy individual were stained with anti–CD57 FITC, anti–CD28 PE, anti–CD8 PerCp, and anti–CD45RA APC. Panel A shows the CD57 (x-axis) versus CD28 (y-axis) staining pattern of memory CD8+ T cells with CD45RA+CD28+events removed to examine the memory CD8+ T cells. The numbers represent the percentages of CD28+CD57, CD28+CD57+, CD28CD57+, and CD28CD57 populations. (B) PBMCs were CFSE labeled and stimulated with SEB for 4 days. Following stimulation, PBMCs were stained with CD57 PE, CD8 PerCP, and CD28 APC. CFSE histograms are demonstrated representing the CD28+CD57 population (upper left histogram), CD28+CD57+ population (upper right histogram), CD28CD57 population (lower left histogram), and CD28CD57+ population (lower right histogram). The numbers indicate the percentages of each population that had divided (calculated using the proliferation platform of FlowJo). These data are representative of experiments conducted on PBMCs from 6 separate individuals and using SEB, anti-CD3, or phytohemagglutinin as the stimulus (C). Wilcoxon matched pairs test demonstrated that the CD28CD57CD8+ T-cell populations contain significantly more proliferation-competent T cells compared with either CD57+CD8+ T-cell population (P = .004). Vertical bars represent the 25th to 75th percentiles.

Close modal

It has been suggested that memory CD8+ T cells that “revert” to a CD45RA+ phenotype represent a population of terminally differentiated fully competent “effector memory” T cells.30,54 55 In order to define further the CD57+CD8+ T-cell population, we sought to examine the relationship between expression of the markers that have been used to define naive, “central memory,” and effector memory populations: CD57, CD27, CD28, CCR7, CD62L, CD45RO, and CD45RA. Figure5 shows how we performed this using 10-color flow cytometry. Figure 5A shows that most of the effector memory (CD45RA+CD27) CD8+ T cells were CD57+. However, only half of the CD57+CD8+ T cells were CD45RA+CD27 (Figure 5D). Analysis of the CD57+CD8+ T cells (Figure 5E-J) revealed that the majority of this population (70%-80%), regardless of their CD45 expression, does not express CD62L, CD28, CD27, nor CCR7. However, a small percentage of the CD57+CD8+ T cells express one or more of these surface markers. This is especially evident when examining the CD45RO+CD57+CD8+ T-cell population, as 30% of this population express CD28 or CD27. Furthermore, when studying the ability of the CD57+CD8+ T-cell population to respond to TCR-mediated stimulation with anti-CD3, similar frequencies of the CD45RO+CD57+CD8+ and CD45RA+CD57+CD8+ T-cell populations produce IFN-γ. Taken together, these data demonstrate that although there is substantial overlap between classical effector memory T cells and the CD57+CD8+ T cells, the former population is only a subset of the CD57+CD8+T-cell population. Similar levels of overlap between expression of CD57, CD27, CD28, CCR7, CD62L, and CD45RA were observed in 5 other healthy individuals (Table 3). In addition, CD57+ T cells divided into smaller subsets are capable of rapid effector cytokine production in response to stimulation. Taken together, these data suggest that all CD57+ T cells (regardless of expression of other phenotypic markers examined here) are of the same functional status and T-cell populations classified as effector memory T cells may be better classified by CD57 expression as the classical CD45RA+CD27 effector memory phenotype does not include all CD57+CD8+ T cells.

Fig. 5.

Ten-color flow-cytometric analysis of CD57+CD8+T cells.

PBMCs from a healthy volunteer were stimulated with anti-CD3 in the presence of BFA for 5 hours. Following stimulation, the cells were surface stained with anti–CD3 Texas red PE (TRPE), anti–CD8 Cy7PE, anti–CD27 APC, anti–CD28 PE, anti–CD45RO Cy7APC, anti–CD45RA FITC, anti–CD57 Alx430, and anti–CD62L Cy5.5PE followed by intracellular staining for anti–IFN-γ Alx594. Plots were gated through CD3 and CD8 followed by additional gating for CD45RA and CD27 or for CD57 then CD45RO or CD45RA as shown by arrows. Consistent patterns of coexpression of these molecules were observed in 6 healthy individuals (Table 3).

Fig. 5.

Ten-color flow-cytometric analysis of CD57+CD8+T cells.

PBMCs from a healthy volunteer were stimulated with anti-CD3 in the presence of BFA for 5 hours. Following stimulation, the cells were surface stained with anti–CD3 Texas red PE (TRPE), anti–CD8 Cy7PE, anti–CD27 APC, anti–CD28 PE, anti–CD45RO Cy7APC, anti–CD45RA FITC, anti–CD57 Alx430, and anti–CD62L Cy5.5PE followed by intracellular staining for anti–IFN-γ Alx594. Plots were gated through CD3 and CD8 followed by additional gating for CD45RA and CD27 or for CD57 then CD45RO or CD45RA as shown by arrows. Consistent patterns of coexpression of these molecules were observed in 6 healthy individuals (Table 3).

Close modal
Table 3.

Coexpression of CD57, CD27, CD28, CCR7, CD62L, and CD45RA by memory CD8+ T cells

Memory subsetHealthy donor% CD27+% CD28+% CCR7+% CD62L+% CD45RA+
CD57+ 35 27 11 27 69 
 65 39 17 35 72 
 41 29 22 43 68 
 54 38 31 51 89 
 31 40 41 47 81 
 23 19 10 29 75 
CD57 80 76 87 85 10 
 93 92 67 91 
 75 79 59 81 
 91 85 72 87 15 
 84 72 81 68 19 
 76 57 70 86 
Memory subsetHealthy donor% CD27+% CD28+% CCR7+% CD62L+% CD45RA+
CD57+ 35 27 11 27 69 
 65 39 17 35 72 
 41 29 22 43 68 
 54 38 31 51 89 
 31 40 41 47 81 
 23 19 10 29 75 
CD57 80 76 87 85 10 
 93 92 67 91 
 75 79 59 81 
 91 85 72 87 15 
 84 72 81 68 19 
 76 57 70 86 

Coexpression patterns of CD27, CD28, CCR7, CD62L, and CD45RA by memory CD57+ and memory CD57CD8+T cells.

Percentage of CD57+ and memory CD57CD8+ T cells that express individual surface markers are shown for 6 healthy, HIV-uninfected individuals.

CD57+ CD8+ T cells are characterized by replicative senescence

The lack of proliferation of CD57+ HIV-specific and other CD8+ T cells suggests that they may have reached replicative senescence. Indeed, it has been shown that CD28CD8+ T cells, the majority of which we have shown are a subset of CD57+CD8+ T cells, have shortened telomeres.19,41 56 To address this possibility, we examined the telomere lengths of CD57+ and CD57 memory and naive CD8+ T cells in 3 healthy volunteers (representative plot in Figure6A). The CD57+CD8+ T cells had shorter telomeres than either CD57 memory or naive CD8+ T cells. Taken together, these results indicate that the CD57+CD8+ T-cell population, as a whole, had undergone more cell divisions than the CD57CD8+ T-cell population. However, the observed differences in telomere length between each subset, although consistent from subject to subject, were small and did not reach statistical significance.

Fig. 6.

Replicative history of CD57+ and CD57 memory and HIV-specific CD8+ T cells.

PBMCs were collected from healthy subjects, and 1 million CD57+ and CD57CD45RO+CD8+ T cells and CD45RA+CD62L+ naive CD8+ T cells were sorted by flow cytometry. Sorted populations were used for telomere measurements using telomere-specific peptide nucleic acid (PNA) followed by flow cytometry. Data were gate-based such that DNA content was consistent between naive and memory CD8+ T cells. Histograms of telomere channel fluorescence are depicted (A). The solid line corresponds to CD57+memory CD8+ T cells (mean fluorescent intensity, 10.1), the dotted line depicts CD57 memory CD8+ T cells (MFI 14.2), and the dashed line represents naive CD8+ T cells (MFI 18.3); MFI of the negative control was 7.6. This experiment was repeated on PBMCs from a total of 3 additional healthy volunteers to ensure reproducibility. Telomere length trends were identical in all 3 subjects. PBMCs then were collected from HIV−1-12 and HIV+subjects13-16 and sorted by flow cytometry for CD57+CD8+ T cells (○) and CD57CD45RO+CD8+ T cells (●) (B). HIV-specific CD57+ (○, bold numbers) or, when possible, CD57 (●, bold numbers) CD8+T cells were additionally sorted from the 4 HIV+individuals based on production of IFN-γ following stimulation with HIV peptides13-16 (panel B, left). At least 10 000 sorted cells of interest were then assayed for TREC using quantitative real-time PCR. Ten is the lower limit of detection for the assay. CD57 memory CD8+ T cells have undergone statistically significantly fewer rounds of proliferation compared with CD57+CD8+ T cells (B, right panel). Vertical bars represent 25th to 75th percentiles.

Fig. 6.

Replicative history of CD57+ and CD57 memory and HIV-specific CD8+ T cells.

PBMCs were collected from healthy subjects, and 1 million CD57+ and CD57CD45RO+CD8+ T cells and CD45RA+CD62L+ naive CD8+ T cells were sorted by flow cytometry. Sorted populations were used for telomere measurements using telomere-specific peptide nucleic acid (PNA) followed by flow cytometry. Data were gate-based such that DNA content was consistent between naive and memory CD8+ T cells. Histograms of telomere channel fluorescence are depicted (A). The solid line corresponds to CD57+memory CD8+ T cells (mean fluorescent intensity, 10.1), the dotted line depicts CD57 memory CD8+ T cells (MFI 14.2), and the dashed line represents naive CD8+ T cells (MFI 18.3); MFI of the negative control was 7.6. This experiment was repeated on PBMCs from a total of 3 additional healthy volunteers to ensure reproducibility. Telomere length trends were identical in all 3 subjects. PBMCs then were collected from HIV−1-12 and HIV+subjects13-16 and sorted by flow cytometry for CD57+CD8+ T cells (○) and CD57CD45RO+CD8+ T cells (●) (B). HIV-specific CD57+ (○, bold numbers) or, when possible, CD57 (●, bold numbers) CD8+T cells were additionally sorted from the 4 HIV+individuals based on production of IFN-γ following stimulation with HIV peptides13-16 (panel B, left). At least 10 000 sorted cells of interest were then assayed for TREC using quantitative real-time PCR. Ten is the lower limit of detection for the assay. CD57 memory CD8+ T cells have undergone statistically significantly fewer rounds of proliferation compared with CD57+CD8+ T cells (B, right panel). Vertical bars represent 25th to 75th percentiles.

Close modal

In order to quantify proliferation differences between CD57+ and memory CD57CD8+ T cells more accurately, we used flow cytometry to sort HIV-specific CD57+CD8+ T cells that produced IFN-γ in response to stimulation with antigen, bulk CD57+CD8+ T cells, and CD57CD45RO+ central memory CD8+ T cells. We then used TREC levels as a measure of proliferative history.49 57 The CD57+ memory CD8+ T-cell subset from healthy and HIV-infected individuals contained statistically significantly fewer TREC compared with the CD57 population (P < .002) (Figure 6B), indicating that the CD57+ population had undergone more rounds of proliferation. In all 4 individuals where we were able to sort HIV-specific CD8+ T cells, the CD57+ HIV-specific CD8+ T cells contained low TREC compared with either CD57 HIV-specific CD8+ T cells or bulk memory CD57CD8+ T cells (Figure 6B, bold numbers), indicating that HIV-specific CD8+ T cells do not prematurely express CD57.

Previous data have suggested that replicatively senescent T cells can be defined by loss of CD28 expression.19,56 58 Because we found discordance in proliferative ability within populations defined by CD57 and CD28, we sought to determine the proliferative history of each population defined in Figure 4. Hence, we sorted by flow cytometry CD8+ T cells that were naive CD45ROCD28+, memory CD57+CD28+, memory CD28CD57, memory CD28+CD57, or memory CD28CD57+, and examined the TREC levels within each population. We found that the TREC levels within these different CD8+ T-cell subsets were as follows: naive T cells > CD28CD57 memory T cells ≥ CD28+CD57 > CD28+CD57+ ≈ CD28CD57+. Sample TREC levels from 1 of 4 healthy subjects are as follows: naive CD8+ T cells 641 TREC/105 cells, memory CD28CD57CD8+ T cells 281 TREC/105 cells, memory CD28+CD57CD8+ T cells 192 TREC/105 cells, memory CD28+CD57+CD8+ T cells 15 TREC/105 cells, and CD28CD57+CD8+ T cells 2 TREC/105 cells. These data indicate that CD28+CD57+ T cells have undergone as many cell divisions as CD28CD57+ T cells and that CD28CD57 T cells have undergone fewer cell divisions than CD57+ T cells irrespective of CD28 expression. Hence, CD57 alone predicts replicative senescence of CD8+ T cells.

CD57+ CD8+ T cells are sensitive to induction of apoptosis

The observation that CD57+ HIV-specific CD8+ T cells fail to proliferate and can no longer be detected by IFN-γ after 48 hours in vitro stimulation suggests that these T cells might be undergoing activation-induced cell death. Alternatively, they may remain in culture but fail to produce IFN-γ at 48 hours. To address these possibilities, we used an HLA-A2 tetramer complexed with an HLA-A2–restricted HIV gag peptide (amino acid sequence SLYNTVATL) in an HLA-A2+ subject (subject 8) with a response to this epitope and found that 51% of tetramer-binding CD8+ T cells were CD57+. After stimulation with SLYNTVATL peptide followed by a 48-hour incubation, only 11% of the tetramer-binding CD8+ T cells were CD57+ (data not shown), suggesting that the CD57+ tetramer binding CD8+ T cells were no longer present in the culture.

To determine if CD57+CD8+ T cells were more prone to undergo activation-induced cell death, we sorted CD57+ and CD57CD8+ T cells and stimulated them with mitogen. After 48 hours these cells were assayed for membrane permeability using propidium iodide. Approximately twice as many CD57+ T cells were positive for propidium iodide compared with CD57 T cells, confirming their increased susceptibility to activation-induced cell death (Figure7A). Uptake of propidium iodide by stimulated CD57+ T cells supports activation-induced cell death of this population but does not determine the mechanism for cell death. Therefore, we stimulated PBMCs from a healthy donor with PHA in the presence of a biotinylated activated caspase 3-binding peptide for 24 hours. Comparing stimulated (CD69+) CD8+ T cells that express CD57 with those that do not, we were able to show that 25 times more CD57+CD8+ T cells bound the activated caspase substrate, indicating that they were, indeed, undergoing apoptosis (Figure 7B).

Fig. 7.

Apoptosis of CD57+CD8+ T cells.

(A) CD8+CD57+ T cells, CD8+CD57 T cells, and CD8CD57 lymphocytes were sorted by flow cytometry followed by PHA stimulation (5 μg/mL). Cells were stained for propidium iodide and analyzed 48 hours following stimulation. (B) PBMCs were stimulated for 12 hours using PHA (5 μg/mL) followed by addition of biotinylated substrate for caspase 3 (Z-VK [Biotin] D(OMe)-FMK, 43 μg/mL) for an additional 12 hours. PBMCs then were stained with anti–CD57 FITC, anti–CD69 APC, anti–CD8 PerCP, and strepavidin PE. Plots shown are gated on live CD8+CD69+ then discriminated based on CD57 expression. This experiment was performed on 3 individuals, and the data trends were identical. Percentages indicate fraction positive for propidium iodide or activated caspase inhibitor.

Fig. 7.

Apoptosis of CD57+CD8+ T cells.

(A) CD8+CD57+ T cells, CD8+CD57 T cells, and CD8CD57 lymphocytes were sorted by flow cytometry followed by PHA stimulation (5 μg/mL). Cells were stained for propidium iodide and analyzed 48 hours following stimulation. (B) PBMCs were stimulated for 12 hours using PHA (5 μg/mL) followed by addition of biotinylated substrate for caspase 3 (Z-VK [Biotin] D(OMe)-FMK, 43 μg/mL) for an additional 12 hours. PBMCs then were stained with anti–CD57 FITC, anti–CD69 APC, anti–CD8 PerCP, and strepavidin PE. Plots shown are gated on live CD8+CD69+ then discriminated based on CD57 expression. This experiment was performed on 3 individuals, and the data trends were identical. Percentages indicate fraction positive for propidium iodide or activated caspase inhibitor.

Close modal

The cytokine IL-15 has been shown to reduce apoptosis59,60and promote proliferation of HIV-specific CD8+ T cells.61 However, we found that although IL-15 dramatically increased the percentage of proliferating CD57CD8+ T cells after SEB or HIV stimulation, there was no increased proliferation of the CD57+ population even at IL-15 concentrations up to 100 ng/mL (data not shown).

We have shown that HIV-specific CD8+ T cells that express the surface molecule CD57 are incapable of proliferating after antigen-specific stimulation in vitro and undergo activation-induced apoptosis. Furthermore, this behavior is not associated with loss of CD28 expression. Some studies have suggested that CD57 and CD28 expression are mutually exclusive in memory T-cell populations.7,35,53,56 However, we found that CD57+CD28+ and CD57CD28 T-cell subsets are clearly identifiable in peripheral blood. By measuring TREC content within different T-cell subsets based on CD57 and CD28 expression, we showed that both proliferative history and proliferative ability are better defined by expression of CD57 than CD28. Taken together, our data show that expression of CD57 rather than lack of CD28 expression defines replicative senescence. Previous interpretations suggesting that proliferative defects are caused by lack of appropriate CD28 costimulation are due to the relatively high (80%) but incomplete association between CD57 expression and loss of CD28.62 63 

CD57 expression is not limited to HIV-specific CD8+ T cells but is associated with the same properties among all T cells and NK cells. These data indicate that cells of both the adaptive arm as well as the innate arm of the immune system are capable of reaching a state of replicative senescence.

From the very low TREC levels and the shortened telomere lengths in CD57+CD8+ T cells, it is clear that this population has undergone more rounds of replication in vivo than CD57 T cells, consistent with observations of others.7,19 36 We additionally show that HIV-specific CD57+CD8+ T cells contain very low TREC levels. Therefore, these T cells have undergone many rounds of cell division, and their inability to divide in response to HIV antigens is not a result of premature expression of CD57. Thus, the lack of proliferative response to HIV does not reflect a defect particular to the HIV-specific CD8+ T-cell population per se, but rather reflects the consequence of an extended replicative history.

While previous studies have suggested an inability of HIV-specific CD8+ T cells to mature to CD45RA+CCR7 phenotypes,30 we found that although most CD57+CD8+ T cells are CCR7, CCR7 expression alone does not determine the ability to proliferate. Using antigen-specific proliferation assays, we showed that CCR7CD8+ T cells in a single HIV-infected individual are capable of replicating in response to antigenic stimulation.

Furthermore, CD8+ T cells belonging to the effector memory population are defined as CD45RA+CCR7CD62LCD27.30,54 55Although all effector memory CD8+ T cells express CD57, only a subset of the CD57+CD8+ T cells are of the effector memory phenotype. The CD57+CD8+ T cells include all effector memory as well as CD8+ T cells of other phenotypes. In addition, all CD57+CD8+T cells (either effector memory or otherwise) (1) are capable of rapid secretion of effector cytokine following antigenic stimulation; (2) cannot proliferate in response to antigen; (3) apoptose following stimulation; and (4) have reached replicative senescence. Hence, the effector memory CD8+ T-cell population may be better defined by CD57 alone rather than by various combinations of CD45RA, CCR7, CD28, CD27, and/or CD62L.

HIV-specific CD8+ T cells can contribute a large proportion (up to 80%) of the total CD57+ T cells, and there is a statistically significant correlation between the percentage of CD57+ HIV gag-specific CD8+ T cells and CD57+CD8+ T cells specific for other HIV antigens. Others have reported increased CD57 expression in persons with chronic CMV infection,9,36,64 even suggesting that all CD57+CD8+ T cells are specific for CMV antigens.65 Thus, the generation of replicative senescence of CD8+ T cells may occur as a result of repetitive antigenic stimulation in vivo by chronic persistent viruses such as CMV and HIV.

Studies aimed at correlating HIV-specific CD8+ T-cell responses with markers of HIV disease have resulted in different conclusions.27,45,66-68 Whereas there is a negative correlation between viral load and specific populations of bulk CD57+CD8+ and CD28CD8+ T cells,69 we did not observe this correlation when measuring expression of CD57 by HIV-specific CD8+ T cells. Since our data support the hypothesis that generation of CD57+ HIV-specific CD8+ T cells is dependent on antigenic stimulation, one might expect to find a positive correlation between viral load and percentage of CD57+ HIV-specific CD8+ T cells. However, our observation that these cells are exquisitely sensitive to activation-induced apoptosis would likely mask a positive correlation at steady state. Furthermore, we do not know the lifespan of this population in vivo in absence of antigenic stimulation. Thus, during persistent antigenic stimulation we propose that HIV-specific CD57+ T cells are constantly being generated and subsequently induced to apoptose after further stimulation.

While the mechanism by which CD57 expression exerts these described phenotypes upon lymphocytes is unknown, and if CD57 is even, itself, involved in apoptosis and lack of proliferation is unknown, the proliferative defects and apoptotic nature observed within HIV-specific CD8+ T cells can be predicted by expression of CD57 on cells that have previously undergone multiple rounds of cell division. The presence of these cells, however, does not reflect a defect particular to the immune response to HIV or an effect limited to any particular virus, but simply reflects the normal consequence of persistent immune activation. Taken together, our data shed light on the functionality and provenance of CD57+ lymphocytes. Hence, in HIV disease, the presence of proliferation-incompetent HIV-specific CD8+ T cells is the result, not the cause, of uncontrolled viral replication. Although several conditions characterized by chronic antigenic stimulation may result in such an immune state, this underlying pathogenesis is a hallmark of untreated HIV infection.

Prepublished online as Blood First Edition Paper, November 14, 2002; DOI 10.1182/blood-2002-07-2103.

Supported by NIH grant AI49990 (N.J.K.) and RO1 AI47603 (N.J.K.), and the Distinguished Young Researcher Award from the UT Southwestern President's Research Council (N.J.K.).

The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked “advertisement” in accordance with 18 U.S.C. section 1734.

1
Carmichael
 
A
Jin
 
X
Sissons
 
P
Borysiewicz
 
L
Quantitative analysis of the human immunodeficiency virus type 1 (HIV-1)-specific cytotoxic T lymphocyte (CTL) response at different stages of HIV-1 infection: differential CTL responses to HIV-1 and Epstein Barr virus in late disease.
J Exp Med.
177
1993
249
256
2
Kaech
 
SM
Ahmed
 
R
Memory CD8+ T cell differentiation: initial antigen encounter triggers a developmental program in naive cells.
Nat Immunol.
2
2001
415
422
3
Murali-Krishna
 
K
Ahmed
 
R
Cutting edge: naive T cells masquerading as memory cells.
J Immunol.
165
2000
1733
1737
4
Wang
 
EC
Lawson
 
TM
Vedhara
 
K
Moss
 
PA
Lehner
 
PJ
Borysiewicz
 
LK
CD8high+ (CD57+) T cells in patients with rheumatoid arthritis.
Arthritis Rheum.
40
1997
237
248
5
Schmidt
 
D
Goronzy
 
JJ
Weyand
 
CM
CD4+ CD7- CD28- T cells are expanded in rheumatoid arthritis and are characterized by autoreactivity.
J Clin Invest.
97
1996
2027
2037
6
Warrington
 
KJ
Takemura
 
S
Goronzy
 
JJ
Weyand
 
CM
CD4+, CD28- T cells in rheumatoid arthritis patients combine features of the innate and adaptive immune systems.
Arthritis Rheum.
44
2001
13
20
7
Sze
 
DM
Giesajtis
 
G
Brown
 
RD
et al
Clonal cytotoxic T cells are expanded in myeloma and reside in the CD8(+)CD57(+)CD28(-) compartment.
Blood.
98
2001
2817
2827
8
Wang
 
EC
Borysiewicz
 
LK
The role of CD8+, CD57+ cells in human cytomegalovirus and other viral infections.
Scand J Infect Dis.
99(suppl)
1995
69
77
9
Evans
 
TG
Kallas
 
EG
Luque
 
AE
Menegus
 
M
McNair
 
C
Looney
 
RJ
Expansion of the CD57 subset of CD8 T cells in HIV-1 infection is related to CMV serostatus.
AIDS.
13
1999
1139
1141
10
Rowbottom
 
AW
Garland
 
RJ
Lepper
 
MW
et al
Functional analysis of the CD8+CD57+ cell population in normal healthy individuals and matched unrelated T-cell-depleted bone marrow transplant recipients.
Br J Haematol.
110
2000
315
321
11
Vingerhoets
 
JH
Vanham
 
GL
Kestens
 
LL
et al
Increased cytolytic T lymphocyte activity and decreased B7 responsiveness are associated with CD28 down-regulation on CD8+ T cells from HIV-infected subjects.
Clin Exp Immunol.
100
1995
425
433
12
Kern
 
F
Khatamzas
 
E
Surel
 
I
et al
Distribution of human CMV-specific memory T cells among the CD8+ subsets defined by CD57, CD27, and CD45 isoforms.
Eur J Immunol.
29
1999
2908
2915
13
Sadat-Sowti
 
B
Debre
 
P
Idziorek
 
T
et al
A lectin-binding soluble factor released by CD8+CD57+ lymphocytes from AIDS patients inhibits T cell cytotoxicity.
Eur J Immunol.
21
1991
737
741
14
Coakley
 
G
Iqbal
 
M
Brooks
 
D
Panayi
 
GS
Lanchbury
 
JS
CD8+, CD57+ T cells from healthy elderly subjects suppress neutrophil development in vitro: implications for the neutropenia of Felty's and large granular lymphocyte syndromes.
Arthritis Rheum.
43
2000
834
843
15
Sadat-Sowti
 
B
Debre
 
P
Mollet
 
L
et al
An inhibitor of cytotoxic functions produced by CD8+ CD57+ T lymphocytes from patients suffering from AIDS and immunosuppressed bone marrow recipients.
Eur J Immunol.
24
1994
2882
2888
16
Frassanito
 
MA
Silvestris
 
F
Cafforio
 
P
Dammacco
 
F
CD8+/CD57 cells and apoptosis suppress T-cell functions in multiple myeloma.
Br J Haematol.
100
1998
469
477
17
Wolthers
 
KC
Miedema
 
F
Telomeres and HIV-1 infection: in search of exhaustion.
Trends Microbiol.
6
1998
144
147
18
Bestilny
 
LJ
Gill
 
MJ
Mody
 
CH
Riabowol
 
KT
Accelerated replicative senescence of the peripheral immune system induced by HIV infection.
AIDS.
14
2000
771
780
19
Effros
 
RB
Allsopp
 
R
Chiu
 
CP
et al
Shortened telomeres in the expanded CD28-CD8+ cell subset in HIV disease implicate replicative senescence in HIV pathogenesis.
AIDS.
10
1996
F17
F22
20
Palmer
 
LD
Weng
 
N
Levine
 
BL
June
 
CH
Lane
 
HC
Hodes
 
RJ
Telomere length, telomerase activity, and replicative potential in HIV infection: analysis of CD4+ and CD8+ T cells from HIV-discordant monozygotic twins.
J Exp Med.
185
1997
1381
1386
21
Pommier
 
JP
Gauthier
 
L
Livartowski
 
J
et al
Immunosenescence in HIV pathogenesis.
Virology.
231
1997
148
154
22
Brander
 
C
Goulder
 
PJ
Luzuriaga
 
K
et al
Persistent HIV-1-specific CTL clonal expansion despite high viral burden post in utero HIV-1 infection.
J Immunol.
162
1999
4796
4800
23
Pantaleo
 
G
Soudeyns
 
H
Demarest
 
JF
et al
Evidence for rapid disappearance of initially expanded HIV-specific CD8+ T cell clones during primary HIV infection.
Proc Natl Acad Sci U S A.
94
1997
9848
9853
24
Soudeyns
 
H
Pantaleo
 
G
New mechanisms of viral persistence in primary human immunodeficiency virus (HIV) infection.
J Biol Regul Homeost Agents.
11
1997
37
39
25
Ostrowski
 
MA
Justement
 
SJ
Ehler
 
L
et al
The role of CD4(+) T cell help and CD40 ligand in the in vitro expansion of HIV-1-specific memory cytotoxic CD8(+) T cell responses.
J Immunol.
165
2000
6133
6141
26
Kalams
 
SA
Walker
 
BD
The critical need for CD4 help in maintaining effective cytotoxic T lymphocyte responses.
J Exp Med.
188
1998
2199
2204
27
Rosenberg
 
E
Billingsley
 
J
Caliendo
 
A
et al
Vigorous HIV-1-specific CD4+ T cell responses associated with control of viremia.
Science.
278
1997
1447
1450
28
Rosenberg
 
ES
Walker
 
BD
HIV type 1-specific helper T cells: a critical host defense.
AIDS Res Hum Retroviruses.
14(suppl 2)
1998
S143
S147
29
Appay
 
V
Nixon
 
DF
Donahoe
 
SM
et al
HIVspecific CD8(+) T cells produce antiviral cytokines but are impaired in cytolytic function.
J Exp Med.
192
2000
63
75
30
Champagne
 
P
Ogg
 
GS
King
 
AS
et al
Skewed maturation of memory HIV-specific CD8 T lymphocytes.
Nature.
410
2001
106
111
31
Voehringer
 
D
Blaser
 
C
Brawand
 
P
Raulet
 
DH
Hanke
 
T
Pircher
 
H
Viral infections induce abundant numbers of senescent CD8 T cells.
J Immunol.
167
2001
4838
4843
32
Mollet
 
L
Sadat-Sowti
 
B
Duntze
 
J
et al
CD8hi+CD57+ T lymphocytes are enriched in antigen-specific T cells capable of down-modulating cytotoxic activity.
Int Immunol.
10
1998
311
323
33
Kern
 
F
Ode-Hakim
 
S
Vogt
 
K
Hoflich
 
C
Reinke
 
P
Volk
 
HD
The enigma of CD57+CD28- T cell expansion—anergy or activation?
Clin Exp Immunol.
104
1996
180
184
34
Hamann
 
D
Kostense
 
S
Wolthers
 
KC
et al
Evidence that human CD8+CD45RA+CD27- cells are induced by antigen and evolve through extensive rounds of division.
Int Immunol.
11
1999
1027
1033
35
Bandres
 
E
Merino
 
J
Vazquez
 
B
et al
The increase of IFN-gamma production through aging correlates with the expanded CD8(+high)CD28(-) CD57(+) subpopulation.
Clin Immunol.
96
2000
230
235
36
Weekes
 
MP
Wills
 
MR
Mynard
 
K
Hicks
 
R
Sissons
 
JG
Carmichael
 
AJ
Large clonal expansions of human virus-specific memory cytotoxic T lymphocytes within the CD57+ CD28- CD8+ T-cell population.
Immunology.
98
1999
443
449
37
Lewis
 
DE
Tang
 
DS
Adu-Oppong
 
A
Schober
 
W
Rodgers
 
JR
Anergy and apoptosis in CD8+ T cells from HIV-infected persons.
J Immunol.
153
1994
412
420
38
Lloyd
 
TE
Yang
 
L
Tang
 
DN
Bennett
 
T
Schober
 
W
Lewis
 
DE
Regulation of CD28 costimulation in human CD8+ T cells.
J Immunol.
158
1997
1551
1558
39
Jaffe
 
JS
Strober
 
W
Sneller
 
MC
Functional abnormalities of CD8+ T cells define a unique subset of patients with common variable immunodeficiency.
Blood.
82
1993
192
201
40
Namekawa
 
T
Wagner
 
UG
Goronzy
 
JJ
Weyand
 
CM
Functional subsets of CD4 T cells in rheumatoid synovitis.
Arthritis Rheum.
41
1998
2108
2116
41
Tarazona
 
R
DelaRosa
 
O
Alonso
 
C
et al
Increased expression of NK cell markers on T lymphocytes in aging and chronic activation of the immune system reflects the accumulation of effector/senescent T cells.
Mech Ageing Dev.
121
2000
77
88
42
Weyand
 
CM
Brandes
 
JC
Schmidt
 
D
Fulbright
 
JW
Goronzy
 
JJ
Functional properties of CD4+ CD28- T cells in the aging immune system.
Mech Ageing Dev.
102
1998
131
147
43
Betts
 
MR
Casazza
 
JP
Patterson
 
BA
et al
Putative immunodominant human immunodeficiency virus-specific CD8(+) T-cell responses cannot be predicted by major histocompatibility complex class I haplotype.
J Virol.
74
2000
9144
9151
44
Pitcher
 
CJ
Quittner
 
C
Peterson
 
DM
et al
HIV-1-specific CD4+ T cells are detectable in most individuals with active HIV-1 infection, but decline with prolonged viral suppression.
Nat Med.
5
1999
518
525
45
Betts
 
M
Ambrozak
 
D
Douek
 
D
et al
Analysis of total HIV-specific CD4+ and CD8+ T cell responses: relationship to viral load in untreated HIV infection.
J Virol.
75
2001
11983
11991
46
Goulder
 
PJR
Tang
 
Y
Brander
 
C
et al
Functionally inert HIV-specific cytotoxic T lymphocytes do not play a major role in chronically infected adults and children.
J Exp Med.
192
2000
1819
1832
47
Murali-Krishna
 
K
Altman
 
JD
Suresh
 
M
et al
Counting antigen-specific CD8 T cells: a reevaluation of bystander activation during viral infection.
Immunity.
8
1998
177
187
48
Karandikar
 
NJ
Crawford
 
MP
Yan
 
X
et al
Glatiramer acetate (Copaxone) therapy induces CD8+ T cell responses in patients with multiple sclerosis.
J Clin Inv.
109
2002
641
649
49
Douek
 
DC
McFarland
 
RD
Keiser
 
PH
et al
Changes in thymic function with age and during the treatment of HIV infection.
Nature.
396
1998
690
695
50
Douek
 
DC
Vescio
 
RA
Betts
 
MR
et al
Assessment of thymic output in adults after haematopoietic stem-cell transplantation and prediction of T-cell reconstitution.
Lancet.
355
2000
1875
1881
51
Lauzon
 
W
Sanchez Dardon
 
J
Cameron
 
DW
Badley
 
AD
Flow cytometric measurement of telomere length.
Cytometry.
42
2000
159
164
52
Rufer
 
N
Brummendorf
 
TH
Kolvraa
 
S
et al
Telomere fluorescence measurements in granulocytes and T lymphocyte subsets point to a high turnover of hematopoietic stem cells and memory T cells in early childhood.
J Exp Med.
190
1999
157
167
53
Horiuchi
 
T
Hirokawa
 
M
Kawabata
 
Y
et al
Identification of the T cell clones expanding within both CD8(+)CD28(+) and CD8(+)CD28(-) T cell subsets in recipients of allogeneic hematopoietic cell grafts and its implication in post-transplant skewing of T cell receptor repertoire.
Bone Marrow Transplant.
27
2001
731
739
54
Sallusto
 
F
Lenig
 
D
Forster
 
R
Lipp
 
M
Lanzavecchia
 
A
Two subsets of memory T lymphocytes with distinct homing potentials and effector functions.
Nature.
401
1999
708
712
55
Hamann
 
D
Baars
 
PA
Rep
 
MH
et al
Phenotypic and functional separation of memory and effector human CD8+ T cells.
J Exp Med.
186
1997
1407
1418
56
Monteiro
 
J
Batliwalla
 
F
Ostrer
 
H
Gregersen
 
PK
Shortened telomeres in clonally expanded CD28-CD8+ T cells imply a replicative history that is distinct from their CD28+CD8+ counterparts.
J Immunol.
156
1996
3587
3590
57
Kimmig
 
S
Przybylski
 
GK
Schmidt
 
CA
et al
Two subsets of naive T helper cells with distinct T cell receptor excision circle content in human adult peripheral blood.
J Exp Med.
195
2002
789
794
58
Batliwalla
 
F
Monteiro
 
J
Serrano
 
D
Gregersen
 
PK
Oligoclonality of CD8+ T cells in health and disease: aging, infection, or immune regulation?
Hum Immunol.
48
1996
68
76
59
Ku
 
CC
Murakami
 
M
Sakamoto
 
A
Kappler
 
J
Marrack
 
P
Control of homeostasis of CD8+ memory T cells by opposing cytokines.
Science.
288
2000
675
678
60
Manjunath
 
N
Shankar
 
P
Wan
 
J
et al
Effector differentiation is not prerequisite for generation of memory cytotoxic T lymphocytes.
J Clin Invest.
108
2001
871
878
61
Kanai
 
T
Thomas
 
EK
Yasutomi
 
Y
Letvin
 
NL
IL-15 stimulates the expansion of AIDS virus-specific CTL.
J Immunol.
157
1996
3681
3687
62
Borthwick
 
NJ
Bofill
 
M
Gombert
 
WM
et al
Lymphocyte activation in HIV-1 infection, II: functional defects of CD28- T cells.
AIDS.
8
1994
431
441
63
Vallejo
 
AN
Brandes
 
JC
Weyand
 
CM
Goronzy
 
JJ
Modulation of CD28 expression: distinct regulatory pathways during activation and replicative senescence.
J Immunol.
162
1999
6572
6579
64
Wang
 
EC
Taylor-Wiedeman
 
J
Perera
 
P
Fisher
 
J
Borysiewicz
 
LK
Subsets of CD8+, CD57+ cells in normal, healthy individuals: correlations with human cytomegalovirus (HCMV) carrier status, phenotypic and functional analyses.
Clin Exp Immunol.
94
1993
297
305
65
Wang
 
EC
Moss
 
PA
Frodsham
 
P
Lehner
 
PJ
Bell
 
JI
Borysiewicz
 
LK
CD8highCD57+ T lymphocytes in normal, healthy individuals are oligoclonal and respond to human cytomegalovirus.
J Immunol.
155
1995
5046
5056
66
Ogg
 
GS
Jin
 
X
Bonhoeffer
 
S
et al
Quantitation of HIV-1-specific cytotoxic T lymphocytes and plasma load of viral RNA.
Science.
279
1998
2103
2106
67
Dalod
 
M
Dupuis
 
M
Deschemin
 
JC
et al
Broad, intense anti-human immunodeficiency virus (HIV) ex vivo CD8(+) responses in HIV type 1-infected patients: comparison with anti-Epstein-Barr virus responses and changes during antiretroviral therapy.
J Virol.
73
1999
7108
7116
68
Gea-Banacloche
 
JC
Migueles
 
SA
Martino
 
L
et al
Maintenance of large numbers of virus-specific CD8+ T cells in HIV-infected progressors and long-term nonprogressors.
J Immunol.
165
2000
1082
1092
69
Lieberman
 
J
Trimble
 
LA
Friedman
 
RS
et al
Expansion of CD57 and CD62L-CD45RA+ CD8 T lymphocytes correlates with reduced viral plasma RNA after primary HIV infection.
AIDS.
13
1999
891
899

Author notes

Richard A. Koup, Vaccine Research Center, National Institute of Allergy and Infectious Disease, National Institutes of Health, 40 Convent Dr, Bethesda, MD 20892; e-mail:rkoup@mail.nih.gov.

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